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from typing import List |
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import gradio as gr |
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import numpy as np |
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import pandas as pd |
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_ORIGINAL_DF = pd.read_csv("./data/benchmark.csv") |
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_METRICS = ["MCC", "F1", "ACC"] |
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_AGGREGATION_METHODS = ["mean", "max", "min", "median"] |
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_TASKS = { |
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"histone_marks": [ |
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"H4", |
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"H3", |
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"H3K14ac", |
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"H3K4me1", |
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"H3K4me3", |
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"H3K4me2", |
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"H3K36me3", |
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"H4ac", |
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"H3K79me3", |
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"H3K9ac", |
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], |
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"regulatory_elements": [ |
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"promoter_no_tata", |
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"enhancers", |
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"enhancers_types", |
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"promoter_all", |
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"promoter_tata", |
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], |
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"RNA_production": [ |
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"splice_sites_donors", |
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"splice_sites_all", |
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"splice_sites_acceptors", |
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], |
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} |
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_BIBTEX = """@article{DallaTorre2023TheNT, |
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title={The Nucleotide Transformer: Building and Evaluating Robust Foundation Models for Human Genomics}, |
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author={Hugo Dalla-Torre and Liam Gonzalez and Javier Mendoza Revilla and Nicolas Lopez Carranza and Adam Henryk Grzywaczewski and Francesco Oteri and Christian Dallago and Evan Trop and Hassan Sirelkhatim and Guillaume Richard and Marcin J. Skwark and Karim Beguir and Marie Lopez and Thomas Pierrot}, |
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journal={bioRxiv}, |
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year={2023}, |
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url={https://api.semanticscholar.org/CorpusID:255943445} |
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} |
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""" |
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_LAST_UPDATED = "Sept 15, 2023" |
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banner_url = "./assets/logo.png" |
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_BANNER = f'<div style="display: flex; justify-content: space-around;"><img src="{banner_url}" alt="Banner" style="width: 40vw; min-width: 300px; max-width: 600px;"> </div>' |
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_INTRODUCTION_TEXT = """The π€ Nucleotide Transformer Leaderboard aims to track, rank and evaluate DNA foundational models on a set of curated downstream tasks introduced in the huggingface dataset [nucleotide_transformer_downstream_tasks](https://huggingface.co/datasets/InstaDeepAI/nucleotide_transformer_downstream_tasks), with a standardized evaluation protocol presented in the "βΉοΈ Methods" tab.\n\n |
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This leaderboard has been designed to provide, to the best of our ability, fair and robust comparisons between models. If you have any question or concern regarding our methodology or if you would like another model to appear in this leaderboard, please reach out to m.lopez@instadeep.com and t.pierrot@instadeep.com. While we may not be able to take into consideration all requests, the team will always do its best to ensure that benchmark stays as fair, relevant and up-to-date as possible.\n\n |
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""" |
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_METHODS_TEXT = """ |
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This leaderboard uses the downstream tasks benchmark and evaluation methdology described in the Nucleotide Transformer paper. We fine-tune each model on each task using a ten-fold validation strategy. For each model and each task, we report the aggregation over the ten-folds for several metrics - the Matthew Correlation Coefficient (MCC), the macro f1-score (F1) and the accuracy (ACC). The Nucleotide Transformer, DNABert and Enformer models have been fine-tuned using the same parameter efficient fine-tuning technique (IA3) with the same set of hyper-parameters. Due to the different nature of their architecture, the HyenaDNA models have been fully-finetuned using the original code provided by the authors. |
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\n\n |
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Please keep in mind that the Enformer has been originally trained in a supervised fashion to solve gene expression tasks. For the sake of benchmarking, we re-used the provided model torso as a pre-trained model for our benchmark, which is not the intended and recommended use of the original paper. Though we think this comparison is interesting to highlight the differences between self-supervised and supervised learning for pre-training and observe that the Enformer is a very competitive baseline even for tasks that differ from gene expression. |
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\n\n |
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For the sake of clarity the tasks being shown by default in this leaderboard are the human related tasks while the original Nucleotide Transformer paper shows performance over both yeast and human related tasks. To obtain the same results as the one shown in the paper, please check all the tasks boxes above. |
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\n\n |
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""" |
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def retrieve_array_from_text(text): |
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return np.fromstring(text.replace("[", "").replace("]", ""), dtype=float, sep=",") |
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def format_number(x): |
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return float(f"{x:.3}") |
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def get_dataset( |
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histone_tasks: List[str], |
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regulatory_tasks: List[str], |
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rna_tasks: List[str], |
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target_metric: str = "MCC", |
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aggregation_method: str = "mean", |
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): |
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tasks = histone_tasks + regulatory_tasks + rna_tasks |
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aggr_fn = getattr(np, aggregation_method) |
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scores = _ORIGINAL_DF[target_metric].apply(retrieve_array_from_text).apply(aggr_fn) |
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scores = scores.apply(format_number) |
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df = _ORIGINAL_DF.drop(columns=_METRICS) |
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df["Score"] = scores |
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df = df.pivot(index="Model", columns="Dataset", values="Score") |
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df = df[tasks] |
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df["All Tasks"] = df.agg("mean", axis="columns").apply(format_number) |
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columns = list(df.columns.values) |
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columns.sort() |
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df = df[columns] |
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df.reset_index(inplace=True) |
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df = df.rename(columns={"index": "Model"}) |
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df = df.sort_values(by=["All Tasks"], ascending=False) |
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leaderboard_table = gr.components.Dataframe( |
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value=df, |
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interactive=False, |
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visible=True, |
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) |
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return leaderboard_table |
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def get_bar_plot( |
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histone_tasks: List[str], |
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regulatory_tasks: List[str], |
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rna_tasks: List[str], |
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target_metric: str = "MCC", |
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aggregation_method: str = "mean", |
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): |
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tasks = histone_tasks + regulatory_tasks + rna_tasks |
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aggr_fn = getattr(np, aggregation_method) |
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scores = _ORIGINAL_DF[target_metric].apply(retrieve_array_from_text).apply(aggr_fn) |
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scores = scores.apply(format_number) |
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df = _ORIGINAL_DF.drop(columns=_METRICS) |
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df["Score"] = scores / len(tasks) |
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df = df.query(f"Dataset == {tasks}") |
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bar_plot = gr.BarPlot( |
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df, |
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x="Model", |
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y="Score", |
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color="Dataset", |
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width=500, |
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x_label_angle=-45, |
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x_title="Model", |
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y_title="Score", |
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color_legend_title="Downstream Task", |
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) |
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return bar_plot |
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with gr.Blocks() as demo: |
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with gr.Row(): |
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gr.Image(banner_url, height=160, scale=1) |
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gr.Markdown(_INTRODUCTION_TEXT, elem_classes="markdown-text") |
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with gr.Row(): |
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metric_choice = gr.Dropdown( |
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choices=_METRICS, |
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value="MCC", |
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label="Metric displayed.", |
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) |
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aggr_choice = gr.Dropdown( |
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choices=_AGGREGATION_METHODS, |
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value="mean", |
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label="Aggregation used over 10-folds.", |
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) |
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with gr.Row(): |
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regulatory_tasks = gr.CheckboxGroup( |
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choices=_TASKS["regulatory_elements"], |
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value=_TASKS["regulatory_elements"], |
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label="Regulatory Elements Downstream Tasks.", |
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info="Human data.", |
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scale=3, |
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) |
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rna_tasks = gr.CheckboxGroup( |
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choices=_TASKS["RNA_production"], |
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value=_TASKS["RNA_production"], |
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label="RNA Production Downstream Tasks.", |
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info="Human data.", |
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scale=3, |
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) |
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histone_tasks = gr.CheckboxGroup( |
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choices=_TASKS["histone_marks"], |
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label="Histone Modification Downstream Tasks.", |
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info="Yeast data.", |
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scale=4, |
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) |
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with gr.Tabs(elem_classes="tab-buttons") as tabs: |
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with gr.TabItem("π
Leaderboard", elem_id="od-benchmark-tab-table", id=0): |
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dataframe = gr.components.Dataframe( |
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elem_id="leaderboard-table", |
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) |
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with gr.TabItem("π Graph", elem_id="od-benchmark-tab-table", id=2): |
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bar_plot = gr.BarPlot( |
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elem_id="leaderboard-bar-plot", |
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x="Models", |
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y="Score", |
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) |
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with gr.TabItem("βΉοΈ Methods", elem_id="od-benchmark-tab-table", id=1): |
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gr.Markdown(_METHODS_TEXT, elem_classes="markdown-text") |
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gr.Markdown(f"Last updated on **{_LAST_UPDATED}**", elem_classes="markdown-text") |
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with gr.Row(): |
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with gr.Accordion("π Citation", open=False): |
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gr.Textbox( |
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value=_BIBTEX, |
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lines=7, |
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label="Copy the BibTeX snippet to cite this source", |
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elem_id="citation-button", |
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show_copy_button=True |
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) |
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histone_tasks.change( |
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get_dataset, |
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inputs=[histone_tasks, regulatory_tasks, rna_tasks, metric_choice, aggr_choice], |
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outputs=dataframe, |
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) |
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regulatory_tasks.change( |
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get_dataset, |
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inputs=[histone_tasks, regulatory_tasks, rna_tasks, metric_choice, aggr_choice], |
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outputs=dataframe, |
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) |
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rna_tasks.change( |
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get_dataset, |
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inputs=[histone_tasks, regulatory_tasks, rna_tasks, metric_choice, aggr_choice], |
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outputs=dataframe, |
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) |
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metric_choice.change( |
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get_dataset, |
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inputs=[histone_tasks, regulatory_tasks, rna_tasks, metric_choice, aggr_choice], |
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outputs=dataframe, |
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) |
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aggr_choice.change( |
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get_dataset, |
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inputs=[histone_tasks, regulatory_tasks, rna_tasks, metric_choice, aggr_choice], |
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outputs=dataframe, |
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) |
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demo.load( |
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fn=get_dataset, |
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inputs=[histone_tasks, regulatory_tasks, rna_tasks, metric_choice, aggr_choice], |
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outputs=dataframe, |
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) |
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histone_tasks.change( |
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get_bar_plot, |
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inputs=[histone_tasks, regulatory_tasks, rna_tasks, metric_choice, aggr_choice], |
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outputs=bar_plot, |
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) |
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regulatory_tasks.change( |
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get_bar_plot, |
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inputs=[histone_tasks, regulatory_tasks, rna_tasks, metric_choice, aggr_choice], |
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outputs=bar_plot, |
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) |
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rna_tasks.change( |
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get_bar_plot, |
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inputs=[histone_tasks, regulatory_tasks, rna_tasks, metric_choice, aggr_choice], |
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outputs=bar_plot, |
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) |
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metric_choice.change( |
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get_bar_plot, |
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inputs=[histone_tasks, regulatory_tasks, rna_tasks, metric_choice, aggr_choice], |
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outputs=bar_plot, |
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) |
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aggr_choice.change( |
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get_bar_plot, |
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inputs=[histone_tasks, regulatory_tasks, rna_tasks, metric_choice, aggr_choice], |
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outputs=bar_plot, |
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) |
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demo.load( |
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fn=get_bar_plot, |
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inputs=[histone_tasks, regulatory_tasks, rna_tasks, metric_choice, aggr_choice], |
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outputs=bar_plot, |
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) |
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demo.launch() |
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